JP2024024565A - Constant temperature/humidity device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a constant temperature/humidity device that can restrain unevenness of temperature distribution in an interior.

SOLUTION: A constant temperature/humidity device comprises a storage chamber, a fan for circulating interior air in the storage chamber, and a warming heater arranged in a flow passage for the interior air, and for warming the interior air. The warming heater comprises a plurality of linear parts, and a curved part connecting end parts of two of the linear parts. A wall part for guiding the interior air to the linear parts is provided.

SELECTED DRAWING: Figure 5

COPYRIGHT: (C)2024,JPO&INPIT

Description

The present disclosure relates to a constant temperature and humidity device.

Patent Document 1 discloses a constant temperature and humidity apparatus that includes a storage chamber that stores bread dough and the like, a heating heater that heats air, and an internal circulation fan that circulates air within the storage. The warming heater in Patent Document 1 warms the air circulated by driving the internal circulation fan to control the temperature of the storage room.

Japanese Patent Application Publication No. 8-84556

The present disclosure provides a constant temperature and humidity device that can suppress unevenness in temperature distribution within a refrigerator.

A constant temperature and humidity device according to the present disclosure includes a storage room, a fan for circulating air inside the storage room, and a heating heater arranged in a flow path of the air inside the storage room for heating the air inside the storage room. The heating heater has a plurality of straight sections and a curved section that connects the ends of the two straight sections, and a wall section that guides the air inside the refrigerator to the straight section. It is provided.

The constant temperature and humidity device according to the present disclosure can suppress unevenness in the temperature distribution of the air flow sent to the storage room.

A perspective view of a constant temperature and humidity device in Embodiment 1 A diagram showing the internal structure of the constant temperature and humidity device in Embodiment 1 from the front side. AA sectional view in Figure 2 BB sectional view in Figure 2 CC sectional view of Figure 2 Enlarged perspective view of heating heater Plan view of heating heater in other embodiments Plan view of heating heater in other embodiments

(Findings, etc. that formed the basis of this disclosure)
At the time when the inventors came up with the present disclosure, there was a technology in which air circulated by driving an internal circulation fan was heated by a heating heater to control the temperature of the storage room.

In such a heating heater, the degree of heating may vary depending on each part of the heating heater. The inventors believe that if the heating level of each part of the heating heater differs, uniform warm air cannot be produced, leading to variations in temperature distribution within the refrigerator, which may lead to variations in the fermentation time of food, for example. I discovered a problem. In order to solve the problem, the inventors have constructed the subject matter of the present disclosure.
The present disclosure provides a constant temperature and humidity device that can suppress variations in temperature distribution within a refrigerator.

Hereinafter, embodiments will be described in detail with reference to the drawings. However, more detailed explanation than necessary may be omitted. For example, detailed explanations of well-known matters or redundant explanations of substantially the same configurations may be omitted.
The accompanying drawings and the following description are provided to enable those skilled in the art to fully understand the present disclosure, and are not intended to limit the subject matter recited in the claims.

(Embodiment 1)
Embodiment 1 will be described below with reference to the drawings.
[1-1. composition]
[1-1-1. Overall configuration]
FIG. 1 is a perspective view of a constant temperature and humidity device in Embodiment 1, and FIG. 2 is a diagram showing the internal structure of the constant temperature and humidity device in Embodiment 1 from the front side. 3 is a sectional view taken along line AA in FIG. 2, and FIG. 4 is a sectional view taken along line BB in FIG.
In the description of this specification, each direction of the constant temperature and humidity device 10, such as front and back and left and right, will be used with reference to FIGS. 1 and 2. For example, the left and right sides in FIGS. 1 and 2 correspond to the left and right sides of the constant temperature and humidity apparatus 10. Further, the front surface and the rear surface of the constant temperature and humidity apparatus 10 are also referred to as the front surface and the rear surface, respectively.
In addition, the X-axis, Y-axis, and Z-axis are appropriately illustrated in the figure. The X-axis, Y-axis, and Z-axis are orthogonal to each other. The Z axis extends in the vertical direction. The Z axis indicates the vertical direction in the installed state of the constant temperature and humidity device 10. The Y-axis extends horizontally. The Y-axis indicates the left-right direction of the constant temperature and humidity device 10. The X-axis indicates the front-rear direction of the constant temperature and humidity device 10. The front and rear directions of the constant temperature and humidity device 10 correspond to the front and back sides described above. The positive direction indicated by the Z-axis arrow indicates the upward direction. The positive direction indicated by the arrow on the Y-axis indicates the right direction. The positive direction indicated by the arrow on the X axis indicates the forward direction.

The constant temperature and humidity device 10 is a device that performs freezing, retardation, preheating, and fermentation operations on the food 1 made of donut dough, bread dough, etc., and is also called a dough conditioner. Note that the food 1 can also be referred to as a stored product, a fermentation target, a target, or the like.
As shown in FIG. 1, the constant temperature and humidity apparatus 10 includes a main body 3 having a heat insulating box 2 with an open front surface. A door 4 for opening and closing the front opening of the heat insulating box body 2 is attached to the main body 3. The heat insulating box body 2 is insulated with a foam type heat insulating material, and the door 4 is formed as a heat insulating door insulated with a heat insulating material. A machine room 5 (FIG. 2) is provided on one left and right side of the main body 3 (in this configuration, on the left side of the heat insulating box 2).

As shown in FIGS. 2 and 4, the machine room 5 includes a compressor 6, a condenser 7, a condenser fan 7F, an evaporator 8, and an evaporator fan 8F that constitute the refrigeration system. As shown in FIG. 2, the upper left side of the heat insulating box 2 is open, and an auxiliary heat insulating material 9 is provided above the machine room 5 to close this opening from the outside. An evaporator 8 and an evaporator fan 8F are arranged within this auxiliary heat insulating material 9. The space within the auxiliary heat insulating material 9 communicates with a cold air passage TC, which will be described later, via a cold air discharge duct 9B partitioned by a cold air passage partition plate 9A.

As shown in FIG. 1, the machine room 5 is surrounded by a panel 5P that constitutes a part of the exterior of the constant temperature and humidity device 10, and a control panel 5CP is provided on the front surface of the panel 5P.
The control panel 5CP is electrically connected to a control device 100 that controls each part of the constant temperature and humidity device 10, and has functions such as inputting various instructions from the user and displaying the operating status and the like. The control device 100 controls each part of the constant temperature and humidity apparatus 10 based on instructions inputted through the control panel 5CP and the detection results of the sensor group 101 that detects the state of each part of the constant temperature and humidity apparatus 10.
In this configuration, the control device 100 is built into the constant temperature and humidity device 10. However, the configuration is not limited to this, and a configuration may be adopted in which the control device 100 is provided outside the constant temperature and humidity device 10 and the constant temperature and humidity device 10 is remotely controlled by the control device 100.

As shown in FIGS. 2 and 3, an inner box 21 is disposed within the heat insulating box 2 with a gap between it and the inner surface of the heat insulating box 2 to form a cold air passage TC. The inner box 21 has a box shape with an open front and is made of a thermally conductive material.
A storage chamber 22 with an open front is provided inside the inner box 21. Above the storage chamber 22, an upper duct plate 23 is arranged with a gap formed between the inner box 21 and the downstream warm air passage TW. Further, a fan cover 24 is disposed at the rear (back side) of the storage chamber 22 with a gap formed between the inner box 21 and the upstream warm air passage TW. In this way, the upper duct plate 23 and the fan cover 24 define a hot air passage TW that continues upward from the back side of the storage chamber 22 .

A plurality of rails 41 are provided on both inner surfaces of the inner box 21 forming both side walls of the storage chamber 22 at intervals in the vertical direction. The left and right rails 41 support a shelf board 42 that extends in the storage room 22 in the front, back, right and left directions, so as to be slidable back and forth. The shelf board 42 is made of a net-like plate material through which air can pass, and is also called a donut net, a screen, or the like. Further, the rail 41 may also be referred to as a donut net holder.
In the constant temperature and humidity device 10 having this configuration, six shelves 42 can be arranged at intervals in the vertical direction. A plurality of foods 1 can be arranged on each shelf board 42 at intervals left and right and front and back. For example, as shown in FIG. 25 foods 1 are placed. In addition, in FIG. 2, only a part of the placed food 1 is shown for convenience of explanation. Note that the size, number, and shape of the foods 1 can be changed as appropriate.

A circulation fan 25 (hereinafter referred to as circulation fan 25), a humidifier 26, and an exhaust air passage TW on the opposite side of the storage room 22 with the fan cover 24 in between, that is, on the back side of the storage room 22, damper 27 is arranged. The circulation fans 25 are arranged with intervals left and right. Each circulation fan 25 sucks air in front of the circulation fan 25 through a suction port provided in the fan cover 24, and sends the air in a centrifugal direction of the circulation fan 25. Note that in FIG. 3, the air flow caused by the circulation fan 25 is indicated by arrows.

The humidifier 26 is disposed below and to the left of the circulation fan 25 and humidifies the air sucked in by the circulation fan 25 under the control of the control device 100. The humidifier 26 is a heating type that includes a tank 26A for storing water and a humidifying heater 26B, but the humidifier 26 is not limited to this configuration. The exhaust damper 27 is arranged below and on the right side of the circulation fan 25, and opens and closes the exhaust port communicating with the cold air passage TC under the control of the control device 100.

A heating heater 28 (hereinafter referred to as heating heater 28) is arranged on the downstream side of the warm air passage TW (above the inner box 21). The warming heater 28 heats the air flowing through the warm air passage TW under the control of the control device 100. Therefore, as shown in FIG. 3, the air blown upward in FIG. 3 by the circulation fan 25 is heated by the heating heater 28 downstream of the warm air passage TW. The air heated by the warming heater 28 is supplied to the communication blow-off section 31F located at the most downstream side of the warm air passage TW.
A dehumidifying fan 29 (hereinafter referred to as dehumidifying fan 29) is provided above the inner box 21. The dehumidifying fan 29 is capable of dehumidifying the storage chamber 22 by introducing air in the cold air passage TC into the inner box 21 under the control of the control device 100.

A blow-off duct plate 32 is provided on the inner surface of the door 4 (the surface on the side of the storage room 22), which partitions a blow-off duct 31 that communicates with the communication blow-off section 31F. The blow-off duct 31 is a space that extends vertically on the front side of the storage chamber 22 and guides air from the communication blow-off section 31F from above to below.
The blow-off duct plate 32 is provided with a blow-off port 32A and a wind direction plate 32B spaced apart from each other vertically. The blow-off ports 32A are provided across the left and right sides of the storage chamber 22, and blow out the air that has flowed into the blow-off duct 31 from the communication blow-off portion 31F into the storage chamber 22 from each blow-off port 32A. The wind direction plate 32B is provided on the opposite side (front side) of the storage chamber 22 in the blow-off duct plate 32, and has a dividing function of guiding the air in the blow-off duct 31 to each blow-off port 32A, and a wind direction of the air blown out from each blow-off port 32A. It has the function to adjust.

The position and shape of each air outlet 32A and each wind direction plate 32B are configured so that air can be blown into each of the spaces partitioned by each shelf board 42. In this configuration, as shown in FIG. 3, each air outlet 32A and each wind direction plate 32B are configured to blow air diagonally downward toward each shelf board 42 from a position above the front of each shelf board 42. There is. Further, each wind direction plate 32B is made longer in order from the top to prevent the air from the communication blow-off portion 31F from reaching the upper level too much. Note that the inclination angle of each wind direction plate 32B is the same. However, the shape and inclination angle of each wind direction plate 32B may be changed as appropriate.

[1-1-2. Configuration of heating heater]
FIG. 5 is a sectional view taken along line CC in FIG. FIG. 6 is an enlarged perspective view of the heating heater.
As shown in FIGS. 5 and 6, the warming heater 28 is supported by a heater mounting member 60. As shown in FIGS.
The heater attachment member 60 includes a flat substrate 61 that is attached to the upper duct plate 23. The board 61 extends in the Y direction of the upper duct plate 23, and both ends of the board 61 are arranged at a predetermined distance from the side wall of the hot air passage TW.
Heater support plates 60A extending upward are integrally provided on both sides of the substrate 61, respectively.

Upper fixing flanges 60B bent outward are provided on the upper portions of the two heater support plates 60A, respectively.
In this way, the heater mounting member 60 is arranged at the upper part of the upper duct plate 23 and at the lower part of the inner upper surface of the inner box 21.

A heating heater 28 is installed on the heater support plate 60A.
The heating heater 28 includes a plurality of straight portions 54 located between each heater support plate 60A, and a plurality of approximately U-shaped curved portions 56 connecting the ends of the straight portions 54 on the outside of each heater support plate 60A. It is equipped with
Both ends of the heating heater 28 are connected to electric wiring, and by supplying electricity to the heating heater via the electric wiring, it is possible to heat the heating heater to a predetermined temperature. The ends of the electrical wiring are wiring connection parts 52A and 52B that are connected to a power source (not shown). Note that the wiring connection portion 52A corresponds to an example of a first wiring connection portion, and the wiring connection portion 52B corresponds to an example of a second wiring connection portion.

To explain in more detail, in this embodiment, three linear portions 54 are arranged at approximately equal intervals in the X direction, which is the air flow direction, between the heater support plates 60A. Further, the straight portions 54 are arranged in two stages in the Z direction, and include a total of six straight portions 54.
By connecting the ends of each straight line part 54, the curved part 56 returns from one wiring connection part 52A, 52B to the other wiring connection part 52A, 52B via each straight part 54 and each curved part 56. It is composed of
As a result, the curved section 56 on the side where the wiring connection parts 52A and 52B are provided is composed of two parts, while the curved part 56 on the other side is composed of three parts. .

A plurality of long holes 65 are formed in the heater support plate 60A. The heating heater 28 is supported by inserting both ends of the linear portion 54 into the elongated hole 65 and positioning the curved portion 56 outside the heater support plate 60A.

The wiring connection parts 52A and 52B are located between the electric wiring and the heating heater 28, and in order to prevent the heat of the heating heater 28 from being transferred to the electric wiring, the entire heating heater 28 is connected when the heating heater 28 is in operation. It is designed to have a temperature lower than that of Therefore, compared to the temperature of the space occupied by the heating heater 28, the temperature of the space near the wiring connections 52A and 52B tends to be lower.

Further, three curved portions 56 are located in the high temperature space SH. Two curved portions 56 and wiring connection portions 52A and 52B are located in the low temperature space SL. The low-temperature space SL has fewer curved portions 56 and the wiring connection portions 52A and 52B are located therein, so it is relatively lower temperature than the space SM where the straight portion 54 is located. Conversely, the high temperature space SH has many curved portions 56, and therefore is relatively hotter than the space SM where the straight portion 54 is located.

As described above, macroscopically, the space occupied by the heating heater 28 has a temperature distribution mainly consisting of three temperature phases.
The heater support plate 60A partitions a space having three types of temperature distribution. That is, the heater support plate 60A has a function of partitioning a portion of the heating heater 28 where the temperature is uniform.
The space SM in which the plurality of straight portions 54 are located corresponds to an example of a first flow path. The high temperature space SH and the low temperature space SL correspond to an example of a second flow path.
Further, the heater cover 70 in the first embodiment corresponds to an example of a wall portion.

A flat heater cover 70 is arranged at the end of the heater support plate 60A in the X direction. The heater cover 70 is configured to close the space between the heater support plate 60A and the side wall of the warm air passage TW.
Note that, for convenience, the heater cover 70 disposed in the high temperature space SH is also referred to as a right side heater cover 70R. The heater cover 70 disposed in the low temperature space SL is also referred to as the left heater cover 70L.

An upper fixing flange 70B bent outward is provided on the upper part of the two heater covers 70, respectively.
Each heater cover 70 is fixed to the inner box 21 via an upper fixing flange 70B.
Each heater cover 70 also includes a fixing flange 76. It is fixed to the heater mounting member 60 via the fixing flange 76 .

The left heater cover 70L includes a wiring support hole 72. A hollow resin cover may be attached to cover the inner periphery of the wiring support hole 72. Thereby, wear caused by various wirings and the wiring support hole 72 can be alleviated.

[1-2. Effect】
Next, the operation of the first embodiment will be explained.
Through the operation of the circulation fan 25, air heated by the heating heater 28 and humidified by the humidifier 26 (which can also be referred to as conditioned air or heated air) is distributed to the hot air passage TW, the communication outlet 31F, and the outlet. It is supplied to the storage chamber 22 through the duct 31 and sucked by the circulation fan 25. Thereby, air circulates between the warm air passage TW and the storage room 22, and it becomes possible to increase the temperature and humidity inside the storage room 22. The heater mounting member 60 and the heater support plate 60A spatially partition the linear portion 54 of the heating heater 28, where the temperature is particularly uniform. In addition, since ventilation of the high temperature space SH and the low temperature space SL is obstructed by the heater cover 70, the warm air passage TW is formed in a portion where the temperature distribution of the heating heater 28 is uniform.
In addition, by operating the dehumidifying fan 29 and opening and closing the exhaust damper 27, cold air in the cold air passage TC is introduced into the storage chamber 22, making it possible to dehumidify the interior of the storage chamber 22.
The control device 100 acquires the temperature and humidity of the storage chamber 22 using a temperature sensor (not shown) and a humidity sensor (not shown) included in the sensor group 101, and maintains the storage chamber 22 at a predetermined target temperature and target humidity. Control each part to achieve the desired results. Thereby, the constant temperature and humidity device 10 can operate to make the storage room 22 an environment suitable for each of thawing, residual heat, and fermentation.

In addition, low-temperature, low-humidity air is generated by operating the compressor 6, condenser 7, condenser fan 7F, evaporator 8, evaporator fan 8F, etc. that constitute the refrigeration system. This cold air circulates clockwise in FIG. 2 through the cold air passage TC around the inner box 21, thereby cooling the inside of the storage chamber 22. The control device 100 acquires the temperature of the storage chamber 22 using a temperature sensor included in the sensor group 101, and controls the storage chamber 22 to a target temperature suitable for freezing. Thereby, the constant temperature and humidity apparatus 10 can be operated to make the storage room 22 an environment suitable for freezing.

When the circulation fan 25 is operated with the heating heater 28 in operation, warm air flows into the warm air passage TW.
At this time, in this embodiment, since the heater cover 70 is provided, ventilation to the high temperature space SH and the low temperature space SL outside the heater support plate 60A can be suppressed. Note that the heater cover 70 is not limited to completely blocking the flow path, and may have a slight gap. With the above configuration, all the air currents do not flow into the high temperature space SH and the low temperature space SL, but are guided to the straight portion 54 of the warming heater 28 located between the heater support plates 60A. Therefore, the straight portion 54 can uniformly heat the airflow, and can send this uniformly heated airflow to the storage chamber 22.

[1-3. Effects, etc.]
As described above, in this embodiment, the storage room 22, the circulation fan 25 of the storage room 22, the heating heater 28 that is disposed in the flow path of the room air and heats the room air, The warming heater 38 includes a plurality of straight sections 54 and a curved section 56 connecting the ends of the two straight sections 54, and is a heater corresponding to a wall section that guides the air inside the refrigerator to the straight section 54. A cover 70 is provided.

According to this configuration, by providing the heater cover 70, all the airflow can be guided to the straight portion 54 of the warming heater 28 located between the heater support plates 60A. Therefore, the straight portion 54 can uniformly heat the airflow, and can send this uniformly heated airflow to the storage chamber 22. Therefore, it is possible to suppress unevenness in the temperature distribution inside the refrigerator.

Further, in the present embodiment, the constant temperature and humidity apparatus 10 further includes a heater mounting member 60 that supports the heating heater 28, and the flow path is arranged in a space SM corresponding to the first flow path in which the straight portion 54 is located. and a high temperature space SH and a low temperature space SL corresponding to the second flow path in which the curved portion 56 is located, and the first flow path and the second flow path are separated by a heater mounting member 60. The heater cover 70 corresponding to the wall blocks the second flow path.

According to this configuration, since the second flow path, which is the high temperature space SH or the low temperature space SL, is closed by the heater cover 70, it is possible to suppress airflow that causes temperature variations from reaching the inside of the refrigerator. Therefore, the straight portion 54 can uniformly heat the airflow, and can send this uniformly heated airflow to the storage chamber 22.

Furthermore, in the present embodiment, the heating heater 28 has a first wiring connection portion 52A provided at one end and electrically connected to the power source, and a first wiring connection portion 52A provided at the other end and electrically connected to the power source. The first wiring connecting portion 52A and the second wiring connecting portion 52B are located near the curved portion 56.

According to this configuration, by arranging the wiring connection parts 52A and 52B whose temperature is lower than the temperature of the entire heating heater 28 on the side of the curved part 56, it is possible to suppress the air inside the refrigerator from passing through the curved part 56. , it is possible to suppress air around the wiring connections 52A and 52B from flowing into the refrigerator.

Further, in the present embodiment, the heater cover 70 corresponding to the wall portion is arranged on the downstream side of the flow path of the internal air.

According to this configuration, by arranging the heater cover 70 on the downstream side of the flow path of the internal air, it is possible to suppress the air that has exchanged heat with the high temperature space SH and the low temperature space SL from being sent to the storage room. . Therefore, the straight portion 54 can send uniformly heated airflow to the storage chamber 22.

Further, in this embodiment, the heating heater 28 is arranged at a higher position than the storage chamber 22.

According to this configuration, since the heating heater 28 and the storage chamber 22 are located close to each other as a flow path for internal air, the generated warm air can be efficiently sent to the storage chamber 22.

(Other embodiments)
As mentioned above, Embodiment 1 has been described as an example of the technology disclosed in this application. However, the technology in the present disclosure is not limited to this, and can also be applied to embodiments in which changes, replacements, additions, omissions, etc. are made.
Therefore, other embodiments will be illustrated below.

FIG. 7 is an enlarged plan view of a heating heater 28 according to another embodiment. As shown in FIG. 7, the heater cover 70D may be arranged at an angle on the downstream side of the heater support plate 60A.
Moreover, FIG. 8 is an enlarged plan view of the heating heater 28 according to another embodiment. As shown in FIG. 8, the heater cover 70U may be arranged upstream of the heater support plate 60A.
Both the heater cover 70D having the configuration shown in FIG. 7 and the heater cover 70U having the configuration shown in FIG. 8 can provide the same functions and effects as in the first embodiment.

Regarding the formation of the heating heater 28, it may be necessary to change it in order to provide a constant temperature function at a higher temperature or to improve thermal efficiency when the device is enlarged. Therefore, for example, the curved portion 56 may be bent so that the straight portions 54 intersect with each other, or the heating heater 28 may be formed in a spiral shape, or other modifications may be made as appropriate. Note that the heating heater 28 may be formed integrally or may be formed by welding.
At this time, it is preferable to appropriately arrange the heater mounting member 60 and the heater cover 70 according to the temperature distribution of the heating heater 28 to separate a space having a uniform temperature distribution.
Further, the heater cover 70 guides a large amount of air to flow in the straight portion 54 by blocking the air passages of the high temperature space SH and the low temperature space SL. Therefore, the position of the heater cover 70 can be arbitrarily placed with respect to the X-axis, and may also be placed at an angle with respect to the Y-axis.

Alternatively, the low temperature space SL and the high temperature space SH may be tilted so as to gradually narrow toward the negative direction of the X axis. That is, since the second flow path is blocked at the upstream side, the hot air passage TW does not communicate with the high temperature space SH and the low temperature space SL, and is connected only to the first flow path, which is the space SM where the straight portion 54 is located. It may be something that In this case, the heater cover 60A that narrows so as to connect only to the straight portion 54 corresponds to an example of the wall portion.

(Additional note)
The following techniques are disclosed by the description of the above embodiments.

(Technology 1)
A constant temperature and humidity device comprising a storage room, a fan for circulating the air inside the storage room, and a heating heater arranged in a flow path of the air inside the storage room for heating the air inside the storage room. The heating heater is a constant temperature heater that includes a plurality of straight sections and a curved section that connects the ends of the two straight sections, and is provided with a wall section that guides air inside the refrigerator to the straight sections. Humidity device.
According to this configuration, since the second flow path, which is a high-temperature space or a low-temperature space, is blocked by the heater cover, it is possible to suppress airflow that causes temperature variations from reaching the inside of the refrigerator. Therefore, the straight portion can uniformly heat the airflow, and the uniformly heated airflow can be sent to the storage room. Therefore, it is possible to suppress unevenness in the temperature distribution inside the refrigerator.

(Technology 2)
The heating heater is further provided with a heater mounting member that supports the heating heater, and the flow path includes a first flow path in which the straight portion is located and a second flow path in which the curved portion is located. The constant temperature and humidity device according to technique 1, wherein the first flow path and the second flow path are separated by the heater mounting member, and the wall portion blocks the second flow path.
According to this configuration, since the second flow path, which is a high-temperature space or a low-temperature space, is blocked by the wall, it is possible to suppress airflow that causes temperature variations from reaching the inside of the refrigerator. Therefore, the straight portion can uniformly heat the airflow, and the uniformly heated airflow can be sent to the storage room.

(Technology 3)
An electrical wiring that electrically connects a power source and the heating heater, a first wiring connection portion provided at one connection portion between the electrical wiring and the heating heater, and the electrical wiring and the heating heater. and a second wiring connection part provided at the other connection part with the curved part, wherein the first wiring connection part and the second wiring connection part are located near the curved part. 2. The constant temperature and humidity device described in 2.
According to this configuration, by arranging the wiring connection part whose temperature is lower than the temperature of the whole heating heater on the side of the curved part, it is possible to suppress the air inside the refrigerator from passing through the curved part, and to prevent the air from passing through the curved part. Air can be prevented from flowing into the refrigerator.

(Technology 4)
The constant temperature and humidity device according to technique 1, wherein the wall portion is disposed on the downstream side of a flow path for internal air.
According to this configuration, by arranging the heater cover on the downstream side of the flow path of the internal air, it is possible to suppress the air that has exchanged heat with the high temperature space and the low temperature space from being sent to the storage room. Therefore, the straight portion can send uniformly heated airflow to the storage room.

(Technology 5)
The constant temperature and humidity device according to technique 1, wherein the wall portion is disposed on the upstream side of the flow path for internal air.
According to this configuration, by arranging the heater cover on the upstream side of the flow path of the internal air, it is possible to suppress the air that has exchanged heat with the high temperature space and the low temperature space from being sent to the storage room. Therefore, the straight portion can send uniformly heated airflow to the storage room.

(Technology 6)
The constant temperature and humidity device according to any one of Techniques 1 to 5, wherein the heater is arranged at a higher position than the storage chamber.
According to this configuration, the heater and the storage chamber are located close to each other as a flow path for the internal air, so that the generated warm air can be efficiently sent to the storage chamber.

As described above, the constant temperature and humidity device of the present disclosure can be applied to homogenize the environment of a storage room.

1 Food (stored items)
2 Heat insulation box 3 Main body 4 Door 10 Constant temperature and humidity device 22 Storage room 24 Fan cover 25 Circulation fan 26 Humidifier 28 Warming heater 31 Blowout duct 32 Blowout duct board 32A Blowout outlet 32B Wind direction board 42 Shelf board 52A, 52B Wiring Connection part 54 Straight part 56 Curved part 60 Heater mounting member 60A Heater support plate 61 Board 70 Heater cover 100 Control device SH High temperature space SL Low temperature space TC Cold air passage TW Warm air passage

Claims (6)

A constant temperature and humidity device comprising a storage room, a fan for circulating the air inside the storage room, and a heating heater arranged in a flow path of the air inside the storage room for heating the air inside the storage room. There it is,
The heating heater includes a plurality of straight parts and a curved part connecting ends of the two straight parts,
A constant temperature and humidity device that is provided with a wall section that guides air inside the refrigerator to the straight section. further comprising a heater mounting member that supports the heating heater,
The flow path includes a first flow path in which the straight portion is located and a second flow path in which the curved portion is located,
The first flow path and the second flow path are separated by the heater mounting member,
the wall interrupts the second flow path;
The constant temperature and humidity device according to claim 1. electrical wiring that electrically connects a power source and the heating heater;
a first wiring connection part provided at one connection part between the electric wiring and the heating heater; a second wiring connection part provided at the other connection part between the electric wiring and the heating heater; further comprising;
the first wiring connection portion and the second wiring connection portion are located near the curved portion;
The constant temperature and humidity device according to claim 1 or 2. The wall portion is disposed on the downstream side of a flow path for internal air,
The constant temperature and humidity device according to claim 1. The wall portion is disposed on the upstream side of a flow path for internal air,
The constant temperature and humidity device according to claim 1. The heating heater is located at a higher position than the storage chamber.
The constant temperature and humidity device according to claim 1 or claim 2.

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